Title:
Effect of Mechanical Splice to Seismic Performance of Precast Column-Foundation Connection
Author(s):
Wei Zhang and Deuckhang Lee
Publication:
Structural Journal
Volume:
Issue:
Appears on pages(s):
Keywords:
energy dissipation, equivalent viscous damping; mechanical splice; performance; precast concrete; residual slip; seismic; stiffness
DOI:
10.14359/51740859
Date:
6/3/2024
Abstract:
Identifying plastic hinge property is one of key factors in successful modeling and subsequent seismic performance evaluation of precast concrete (PC) moment frame systems. Tight mechanical splices are also essentially required in precast connections, and their residual slip can greatly affect the plastic hinge length and finally the emulative performance level of PC seismic force-resisting system (SFRS). However, most of the existing models are not directly applicable in current forms to estimate the plastic hinge length of precast connection with mechanical splices. To address the effects of the residual slip induced in a mechanically-spliced reinforcement system and its non-uniform stiffness due to a splicing device (or coupler), a detailed nonlinear finite element (FE) analysis model was developed in this study, where plasticity-based constitutive models and unique connector element were adopted for concrete and mechanically-spliced reinforcements, respectively. Existing test results of column-foundation connections were utilized to verify the analytical approach. On this basis, a robust macro modeling method was also proposed for nonlinear cyclic analysis of PC moment frame systems with mechanical splices in this study. It appears that the magnitude of the residual slip in mechanical splices can greatly undermine the lateral stiffness, energy dissipation capacity, and equivalent viscous damping ratio of PC moment connections, and the proposed macro modeling approach can reasonably capture their behavioral characteristics.